ES2932077T3 - A tactile and pressure sensing system with different top layers - Google Patents

Abstract

In the sensing system (S) according to the present invention, a structure is provided that detects the point of application, the intensity and the area of the applied force and pressure, together with the touch, and the forces applied in the vertical direction to the sensor as well as the combined forces, which has reduced power consumption. Said detection system (S) comprises an intermediate layer (1); an upper layer (4) located on the intermediate layer (1); a light source (2) located under the intermediate layer (1); an image sensor (3) located under the intermediate layer (1); a first fiber optic bundle (5a) comprising a plurality of fiber optic cables placed so that one of its tips faces the light source (2) and other tips face said intermediate layer (1); a second fiber optic bundle (5b) comprising a plurality of fiber optic cables, the tips of which are paired with a pixel of the image sensor (3) and other tips are positioned opposite said intermediate layer (1); a control unit that analyzes the image captured by the image sensor (3) using image processing techniques to calculate a force applied to the intermediate layer (1); and a data link (6) for data communication between the image sensor (3) and the control unit. (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

A tactile and pressure sensing system with different top layers

Relevant technical field

The present invention relates to detection systems that are used especially in robotic systems.

Background art

In order to explore those areas that can be dangerous for humans (for example, different planets, underground tunnels or caves), exploration robots are used. Scanning robots comprise various sensors to detect objects in the area to which they are sent and to identify the characteristics of those objects. One of the sensors used in such scanning robots are touch sensors. Through tactile sensors, the presence of certain objects and some physical characteristics of them such as pressure can be detected.

Conventional touch sensors comprise a light source positioned below a resilient surface and a light sensing element for sensing the amount of light reflected from said surface, as described in US2010155579A1. In such tactile sensors, when a force is applied to the elastic surface, the elastic surface moves closer to the light source and the light sensing element. As a result of such an approximation, the amount of light incident on the light detection element increases. The amount of light detected by the light sensing element and the resiliency properties of the surface are used to calculate the amount of force applied to the surface. However, in this embodiment, the number of light sources that can be placed under the surface of the unit and light detection elements is limited, and it is cumbersome to process data received from a large number of detection elements. of light.

Said problems are solved by means of a module described in the document WO2014011126A1. Said module comprises an elastic material, which is covered with a layer that provides light reflection; a CMOS or CCD image sensor; at least one light source; a plurality of first fiber optic cables, some ends of which are separated from the surrounding environment through said layer being located below the layer and other ends of which are in connection with said light source, wherein said first cables fiber optics carry light beams from the light source to said layer; a plurality of second optical fiber cables, tips of which are separated from the surrounding environment through said layer being located under the layer and being directed towards the layer and other tips of which are in connection with said image sensor such that each second optical fiber cable is paired with a pixel of the image sensor, wherein light rays reflected from the layer are transferred to the image sensor by said second optical fiber cables; a processor that calculates each individual force applied to the layer according to the changes of light intensity of each pixel connected with a second fiber cable, from a photo frame generated by the image sensor in response to the displacement of the layer using techniques of image processing. In the module described in the document WO2014011126A1, when the elastic material comes into contact with an object, a deformation is generated in the elastic material and said layer (for example, displacement of the layer towards the fiber optic cables). As a result of such displacement, the amount of light reflected from the layer to the fiber optic cable is changed. Said change in the amount of light is detected as a color change in the photo frame generated on the image sensor. The processor applies image processing techniques to said photo frame to measure the color changes of the photo and thus the amount of layer shift. Based on the amount of displacement calculated, the applied force on the elastic material is also calculated. However, due to the fact that in said embodiment the detection is performed only based on the light level, an improvement is needed.

Another patent document US4547668A describes a two-dimensional pressure sensor. Said pressure sensor comprises a light source; a light transmission fiber termination array comprising a plurality of fibers for transmitting said light from said light source and a plurality of fibers for receiving reflected light; a secondary array of transmission fibers comprising terminations of said transmission fibers located at a distance from said array of light transmission fiber terminations, said terminations positioned to receive light from said light source; a secondary array of receive fibers, comprising terminations of said receive fibers located at a distance from said matrix of light transmission fiber terminations; a retroreflective material located at a distance above said matrix; a semitransparent deformable medium positioned between said matrix and said retroreflective material, said semitransparent deformable medium supporting said retroreflective material; a flexible membrane located adjacent to the side of said retroreflective material furthest from said matrix; and means located adjacent said receive fiber subarray, for detecting said reflected light transmitted by said light fibers from said array to said receive fiber subarray.

Another patent document WO2005029028A1 describes an optical touch sensor. Said optical touch sensor comprises a sensing part comprising a transparent elastic body and a plurality of groups of markers provided on said body, each group of markers being composed of a plurality of markers of colors, with the markers constituting different groups of markers having different colors for each group, said elastic body having an arbitrary curved surface; a photography device for taking an image of the behavior of the colored markers when said curved surface of the elastic body contacts an object to obtain image information of the markers, and a force vector distribution reconstruction device for includes a transfer function by which a force vector applied to the surface is reconstructed from information regarding the behavior of the markers that is obtained from the image information of the markers, and said distribution reconstruction device force vector that reconstructs the forces applied to said surface from said information regarding the behavior of the markers using the transfer function.

US4816811A describes a raster scan CRT, in which the electron beam from a CRT electron gun is incident on the phosphorescent screen of the CRT in a sequential pattern, line by line, from top to bottom. As the electrons strike the CRT's phosphorescent screen, the surface glows. By controlling the deflection of the raster beam using a CRT controller, it is possible to create images at any position on the CRT screen. In addition, a touch sensitive overlay is adapted to be superimposed on the face of the display screen. The application of a deflecting force causes a substantial level of light to become trapped within the overlap. This level of trapped light is processed using signal detection circuitry.

Brief description of the invention

The detection system according to the present invention that detects touch comprises at least one intermediate layer; at least one upper layer located on top of the intermediate layer; at least one light source located below the intermediate layer; at least one image sensor located below the intermediate layer; at least a first bundle of optical fibers comprising a plurality of fiber optic cables positioned so that some tips of which face the light source and other tips of which face said intermediate layer, and transmit light obtained from the light source to the upper layer located on the intermediate layer; at least a second bundle of optical fibers comprising a plurality of fiber optic cables, tips of which are paired with at least one image sensor pixel and other tips of which are positioned facing the intermediate layer, and transmit the image of the upper layer located in the intermediate layer to the image sensor; at least one control unit that analyzes the image captured by the image sensor using image processing techniques to calculate an applied force on the intermediate layer; and at least one data link for data communication between the image sensor and the control unit. According to the claimed invention, said upper layer further comprises a phosphor and/or any other material that stores a part of the light itself but starts to emit light when the light from the light source is cut off.

In the detection system according to the present invention, the light rays received from the light source pass through the intermediate layer onto the upper layer through the first bundle of optical fibers. An image of the top layer is transmitted to the image sensor via the second bundle of optical fibers. Here, when a force is applied through the top layer onto the middle layer, an image frame of a shape (pattern) change, color change, or brightness change of the top layer captured by the image sensor it is analyzed by the control unit using image processing techniques so that the force applied through the top layer onto the intermediate layer can be calculated.

Object of the invention

An object of the present invention is to provide a detection system suitable for use in robotic systems.

Another object of the present invention is to provide a detection system capable of detecting touch.

Another object of the present invention is to provide a detection system with reduced power consumption. Another object of the present invention is to provide a detection system where it is detected whether it is subjected to a certain force.

Another object of the present invention is to provide a detection system in which the point of application and the area of the applied force are detected.

Another object of the present invention is to provide a detection system in which the applied pressure is detected.

Yet another object of the present invention is to provide a detection system capable of detecting forces applied in a vertical direction to the sensor, as well as combined forces.

Description of the drawings

Illustrative embodiments of the detection system according to the present invention are illustrated in the accompanying drawings, in which:

vista lateral del sistema de detección.Figure 1 is a

side view of the detection system.

Figure 2 is a perspective view of an exemplary embodiment of the detection system.

vista lateral de otra realización ejemplar del sistema de detección.Figure 3 is a perspective view of an exemplary embodiment of the detection system as used. Figure 4 is a

side view of another exemplary embodiment of the detection system.

vista lateral de otra realización ejemplar del sistema de detección según se usa.Figure 5 is a

side view of another exemplary embodiment of the detection system as used.

vista lateral de otra realización ejemplar del sistema de detección.Figure 6 is a

side view of another exemplary embodiment of the detection system.

All parts illustrated in the drawings are individually assigned a reference number and the corresponding terms of these numbers are listed below:

Detection system (S)

Intermediate layer (1)

Light source (2)

Image sensor (3)

Top layer (4)

First bundle of optical fibers (5a)

Second bundle of optical fibers (5b)

Data Link (6)

Pattern (7)

Outer shell (8)

Elastic element (9)

Obstacle (10)

Distance element (11)

Description of the invention

With advanced robotics technology, senses such as sight, hearing, and touch can be detected by sensor systems. In particular, in exploration robots used to explore those areas that are dangerous to human beings or cannot be reached by mankind, the characteristics of the areas being explored can be accurately detected by such sensor systems. Therefore, with the present invention, a detection system capable of detecting touch is provided.

The detection system (S) according to the preamble of the presently claimed invention, as illustrated in figures 1-6, comprises at least one intermediate layer (1); at least one upper layer (4) located on the intermediate layer (1); at least one light source (2) located below the intermediate layer (1) (distant from the upper layer (4)); at least one image sensor (3) (ie, a CCD, CMOS, etc. sensor) located below the intermediate layer (1) (distant from the upper layer (4)); at least a first bundle of optical fibers (5a) comprising a plurality of fiber optic cables placed so that some tips of which face the light source (2) and other tips of which face said intermediate layer (1), and transmit the light obtained from the light source (2) to the upper layer (4) located in the intermediate layer (1); at least a second bundle of optical fibers (5b) comprising a plurality of fiber optic cables, some tips of which are paired with at least one pixel of the image sensor (3) and other tips of which are placed facing each other. said intermediate layer (1), and transmitting the image of the upper layer (4) located on the intermediate layer (1) to the image sensor (3); at least one control unit (not shown) that analyzes the image captured by the image sensor (3) using image processing techniques to calculate a force applied to the intermediate layer (1); and at least one data link (6) for data communication between the image sensor (3) and the control unit. Said data link (6) can be a wired connection or a wireless connection.

In a preferred embodiment, said upper layer (4) comprises at least one pattern (7), as shown in figures 2 and 3. The pattern (7), which preferably has a square checkerboard shape, deforms towards the intermediate layer (1), when exposed to a force, as shown in figure 3. An image frame of the upper layer (4) captured by the image sensor (3) is processed in said control unit with the In order to determine in which area the pattern (7) has been deformed and to what extent and how, and, consequently, the force and pressure applied on the intermediate layer (1) is calculated.

In another preferred embodiment, said upper layer (4) comprises a material that changes color with force. In an illustrative embodiment, the top layer (4) comprises a polarized film. If a force is applied to the polarized film, color changes are observed in the film based on the intensity of the applied force. Since the image frame of the upper layer (4) captured by the image sensor (3) is analyzed by the control unit using image processing techniques, the extent of color change in the polarized film is detected. Since said color change and color change area are associated with the force applied on the upper layer (4), the extent of the force and pressure applied through the upper layer (4) on the middle layer (4) is also calculated. one ).

In another preferred embodiment, the upper layer (4) comprises a piezochromic material. Piezochromic materials change color with pressure. Said color change varies depending on the pressure applied. In this embodiment, since the image frame of the upper layer (4) captured by the image sensor (3) is analyzed by the control unit using image processing techniques, the color change in the piezochromic material is calculated. , the area of color change and thus the extent of the force and pressure applied through the top layer (4) onto the intermediate layer (1). Piezochromic materials can be reversible (they return to their original color when the force applied to them is removed) or irreversible (they do not return to their original color when the force applied to them is removed). In a preferred embodiment, the piezochromic material used in the detection system (S) is reversible. Thus, when the force applied to the intermediate layer (1) is removed, the piezochromic material returns to its original color and when a different force is applied to the intermediate layer (1), the newly applied force is also detected. In an alternative embodiment, said top layer (4) comprises a first layer placed on its side close to the surrounding environment and preferably containing a reversible piezochromic material (or any other type of top surface), and a second layer placed next to it. distant from the surrounding environment and containing irreversible piezochromic material. In this embodiment, when a force is applied externally on the intermediate layer (1), a force and pressure are also applied on the second layer. However, when a force higher than the expected force is applied to the intermediate layer (1), a force higher than the threshold value is imposed on the second layer and the color of the second layer changes permanently due to the irreversible piezochromic material. Of the same. In this way, it is detected whether or not a force higher than the predicted force is applied to the intermediate layer (1), as well as the magnitude of the applied force based on the color change of the second layer.

In another preferred embodiment, the upper layer (4) comprises at least one outer layer (8) that is elastic and resistant to light, at least one elastic element (9) placed under the outer layer (8) and that is transparent. and preferably in the form of a gel, and a plurality of (for example, at least in two rows) obstacles (10) placed on the elastic element (9) and having a light-resistant particle shape so that their color is different to that of the outer layer (8), as shown in figures 4 and 5. As shown in figure 5, when a force is applied through the upper layer (4) on the intermediate layer (1), said outer layer (8) pushes the obstacles (10) to the right and left sides and approaches the middle layer (1). As a result of this movement, color changes are seen in the image frame of the upper layer (4) captured by the image sensor (3). By analyzing said image frame by the control unit using image processing techniques, the extent of the color change is determined. Thus, the amount of force applied through the top layer (4) onto the intermediate layer (1) is calculated.

According to the claimed invention, said upper layer (4) comprises a phosphor and/or any other material that stores part of the light in itself but starts to emit light when the light from the light source is cut off. In this embodiment, said light source (2) is activated at certain intervals in order to increase the energy of the phosphor and/or similar material. In this way, even if the light source (2) is turned off, the phosphor and/or similar material emits light for a certain period of time. In this embodiment, when a force is applied through the upper layer (4) onto the intermediate layer (1), the brightness of an image frame section of the upper layer (4) captured by the image sensor (3 ) that is subjected to a force is higher than those sections that are not subjected to a force. In said picture frame, the brightness of different pixels is compared so that the force applied through the top layer (4) onto the middle layer (1) can be calculated.

In an alternative embodiment, said upper layer (4) partially transmits light (for example, a mirror film or a fine porous structure such as a veil). As is known, such structures normally transmit light, but if an opaque object that blocks light transmission is placed behind them, it reflects the light back. In this embodiment, the light rays received from the light source (2), which are transmitted through the intermediate layer (1) onto the upper layer (4) through the first bundle of optical fibers (5a), normally they are transmitted to the surrounding environment (and an image of the surrounding environment is present in the image captured by the image sensor (3)). However, if an object is placed on the middle layer (1), the light rays pass through the upper layer (4) and hit the object and are reflected back from the object. An image of said object is also present in the image frame captured by the image sensor (3). The image frame captured by the image sensor (3) is analyzed by the control unit using image processing techniques so that the force applied through the top layer (4) onto the intermediate layer (1) can be calculated.

In another alternative embodiment, the first bundle of optical fibers (5a) and/or the second bundle of optical fibers (5b) are multi-piece bundles. In this embodiment, the first bundle of optical fibers (5a) and/or the second bundle of optical fibers (5b) comprise a first section that includes a plurality of optical fiber cables; a second section that includes a plurality of fiber optic cables; and a carrier fiber optic cable, to the end of which one end of each fiber optic cable in said first section is connected and to another end of which one end of each fiber optic cable in said second section is connected, the diameter of which is greater than that of the fiber optic cables in the first section and the second section, and which transmits the lights carried by the fiber optic cables in the first section to the fiber optic cables in the second section and the lights carried by the fiber optic cables in the second section to the fiber optic cables in the first section. In this way, in the embodiments where the length of the optical fiber cables must be long, it will be sufficient that one or a limited number of optical fiber cables (carrier fiber) be long, instead of a high number of transmission cables. optical fiber. In another embodiment of the carrier fiber, the diameter of said carrier fiber optic cable is less than that of the first section and the second section. In this embodiment, in order to have exact matching of each fiber optic cable in the first section with each fiber optic cable in the second section (i.e. to ensure that light rays from different fiber optic cables do not interfere with each other), the first optical bundle (5a) and/or the second bundle of optical fibers (5b) also comprise at least two optical elements, each one interposed between the carrier optical fiber cable and the first section, and between the carrier fiber optic cable and the second section. Said optical elements prevent the light rays flowing through the carrier fiber optic cable from interfering with each other.

In an alternative embodiment shown in figure 6, the detection system comprises at least two distance elements (11), placed between said upper layer (4) and the intermediate layer (1), and that maintain the upper layer (4 ) and the intermediate layer (1) separated from each other. In this embodiment, said upper layer (4) can either be elastic or it can be rigid.

In the detection system (S), the light rays received from the light source (2) are passed through the intermediate layer (1) and onto the upper layer (4) through the first bundle of optical fibers ( 5a). An image of the upper layer (4) is transmitted to the image sensor via the second bundle of optical fibers (5b). Here, when a force is applied through the upper layer (4) onto the intermediate layer (1), an image frame of the change in shape (and/or pattern (7)), change in color or change in color is analyzed. gloss of the upper surface (4) captured by the image sensor (3) by the control unit using image processing techniques, so that the force applied through the upper layer (4) on the layer can be calculated intermediate (1). In addition, thanks to the displacement area represented by the color change area in the obtained image, the pressure applied in any direction (for example, transverse angles) is calculated. In addition, with the detection of a change in a pattern (7) of the upper layer (4), forces applied on the upper layer (4) from different angles (for example, right angles) can also be detected, as well as their address.

Claims (1)

1. A detection system (S) that detects touch, comprising: - at least one intermediate layer (1); - at least one upper layer (4) located on the intermediate layer (1); - at least one light source (2) located below the intermediate layer (1); - at least one image sensor (3) located below the intermediate layer (1); - at least a first bundle of optical fibers (5a) comprising a plurality of fiber optic cables placed so that some tips of which face the light source (2) and other tips of which face the said intermediate layer (1), and that transmits the light obtained from the light source (2) to the upper layer (4) located on the intermediate layer (1); - at least a second bundle of optical fibers (5b) comprising a plurality of fiber optic cables, some tips of which are paired with at least one pixel of the image sensor (3) and other tips of which are placed facing each other to said intermediate layer (1), and transmitting the image of the upper layer (4) located on the intermediate layer (1) to the image sensor (3); - at least one control unit that analyzes the image captured by the image sensor (3) using image processing techniques to calculate a force applied to the intermediate layer (1); Y - at least one data link (6) for data communication between the image sensor (3) and the control unit characterized in that said upper layer (4) comprises a phosphor and/or any other material that it stores in itself a part of the light but becomes light emitting when the light from the light source is cut off.